Self-orienting guide shoe

ABSTRACT

A guide shoe that utilizes an eccentric nose attached to a cylindrical body that has spiraled, ridged blades extending outward from the body. An orientation system is attached between the body and a hollow shaft. The orientation system is designed to allow free rotation of the body and nose about the shaft during the insertion of the tubing into the hole. It does this by providing clearance between a pawl and notches on the cylindrical body. Indexing of the eccentric nose is provided by a slight retraction of the tubing string in the well hole. Friction between the well hole and ridged blade causes the cylindrical body to rotate about the shaft and lock into an oriented position. The guide shoe is attached to the tubing string by a threaded female connection mating to the matching male connection on the tubing string.

CROSS REFERENCE TO RELATED APPLICATIONS

Not Applicable

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH AND DEVELOPMENT

Not Applicable

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to guide shoes for oil well development and particularly to a self-orienting guide shoe for oil well development

2. Description of the Prior Art

The process of drilling for oil is a multi-step process. First, a borehole is drilled into the ground using a drill bit and drill motor attached to the bottom of the drill string. Drilling mud lubricates the borehole and provides the means to power the drill motor. After the borehole has been drilled to a sufficient depth, tubing is inserted into the borehole. Extended reach wells requires a significant axial force to be placed upon the tubing string during the insertion process. Once the tubing reaches final depth, the bore hole and tubing are cleaned and clearance between the tubing and bore hole is provided by pumping high pressure fluid into the tubing string and then out through a guide shoe, which forces debris upward and out of the hole. This is followed by high pressure pumping of cement to secure the tubing into the ground and for zonal isolation. The guide shoe is attached to the bottom of the tubing string and is used to negotiate well bores that have a high degree of deviation, ledges, and depths inherent in extended reach directional drilling. Advanced technology utilized in current guide shoe design includes a rotating eccentric nose that can better negotiate well deviations, and a means of centralization to reduce affects of friction to achieve greater total depth. A problem with the prior art devices is that they do not address the need to overcome friction of the guide shoe and the well bore to orient the eccentric nose to an advantageous position that would enable to the guide shoe to negotiate extreme deviations and ledges in the hole. Rotating guide shoes have the problem of slipping on obstacles, which make progress inefficient, if not impossible. Some guide shoes use reamers to cut through the obstructions without rotating, this is better than simply spinning in place, but can cause difficulties, depending on the material contacted.

BRIEF DESCRIPTION OF THE INVENTION

The instant invention over comes these problems. It is a guide shoe that utilizes an eccentric nose attached to a cylindrical body that has spiraled, ridged blades extending outward from the body. An orientation system is attached between he body and a hollow shaft. The orientation system is designed to allow free rotation of the body and nose about the shaft during the insertion of the tubing into the hole. It does this by providing clearance between a pawl and notches on the cylindrical body. Indexing of the eccentric nose is provided by a slight retraction of the tubing string in the well hole. Friction between the well hole and ridged blade causes the cylindrical body to rotate about the shaft and lock into an oriented position.

The guide shoe is attached to the tubing string by a threaded female connection mating to the matching male connection on the tubing string.

The method for using the self-orienting guide shoe begins with attachment of the guide shoe to the tubing string. Next, the connected tubing is inserted into the borehole. Additional tubing sections are connected in series as needed to reach final depth. The step of inserting the casing into the borehole may include axial force provided by external sources such as the drill rig and or drilling mud. When encountering an obstruction preventing the tubing from further insertion, the tubing string is retracted a small amount causing the eccentric nose of the guide shoe to rotate into the first orientation position. Successive insertions and retractions continue to rotate and thus orient the nose of the shoe until an advantageous position of the eccentric nose vis-à-vis the obstruction is achieved, allowing the tubing to continue the insertion process to the planned final depth.

Thus, there is no need to use reamers to cut though obstructions. Moreover, because the nose locks into a position, it does not rotate freely when it meets an obstruction. The eccentric nose is simply aligned with the obstruction and then pushed forward and past it.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of the invention.

FIG. 2 is a detail side view of a well bore hole showing the invention encountering an obstacle.

FIG. 3 is a detail side view of a well bore hole showing the invention after it has been rotated and locked to avoid the obstacle.

FIG. 4 is a detail side cut-away view of a well bore hole showing the invention after it has been rotated and locked to avoid the obstacle, showing the internal orienting mechanism.

FIG. 5 is a detail side cut-away view of a well bore hole showing the invention encountering an obstacle, showing the internal orienting mechanism.

FIG. 6 is an enlarged side cut-away view of the invention showing the internal orienting mechanism in the unlocked position.

FIG. 7 is an enlarged side cut-away view of the invention showing the internal orienting mechanism in the locked position.

FIG. 8 is a detail view of the internal orienting mechanism shown in the unlocked position.

FIG. 9 is a detail view of the internal orienting mechanism shown in the locked position.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to FIG. 1, the invention is shown in a side view. The guide shoe 1 has an eccentric nose 2 attached to a cylindrical body 3. The cylindrical body 3 has a set of spiraled, ridged blades 4 extending outward from the body as shown. These ridged blades act as a centralizer for the shoe. As with other guide shoes, the nose 2 has an exit port 2 a for the placement of fluids into the borehole.

The body 3 is attached to a hollow shaft 5 (see FIG. 4) by the orientation system 6 (see FIG. 4, e.g.). The orientation system is designed to allow free rotation of the body 3 and the nose 2 about the shaft 5 while the tubing is inserted into a hole.

FIG. 2 is a detail side view of a well borehole showing the invention encountering an obstacle. As discussed above, the orientation system (discussed in detail below) is used to reorient the nose 2 of the device when it encounters obstacles in its path. In this figure, the guide shoe 1 is in a well borehole 100 has reached an obstacle 110. When this happens, the guide shoe can be backed off, and rotated to a new position in which the eccentric nose can work around the obstacle.

FIG. 3 is a detail side view of a well bore hole showing the invention after it has been rotated and locked to avoid the obstacle. In this figure, the eccentric nose 2 is now in position to avoid the obstacle 110 and proceed further into the borehole 100.

FIGS. 4 and 5 are similar to that of FIGS. 2 and 3, except that they are side cut-away views of a well bore hole showing. Here, the internal components of the device are shown. The shaft 5 has the orienting mechanism 6 installed around it as shown. The orienting mechanism 6 has a ratchet and pawl mechanism 6 a (discussed further below). The mechanism is designed to lock the shaft 5 in place when the pawn is properly set. When the pawl is released, the shaft 5, and body 3 are free to rotate.

Indexing of the eccentric nose 2 is provided by a slight retraction of the tubing string (not shown) in the well hole 100. Friction between the well hole 100 and ridged blades 4 causes the cylindrical body 3 to rotate about the shaft 5 until the pawl reaches the next stop in the ratchet, where it locks into an oriented position (e.g., that shown in FIG. 5). Note that the orientation of FIG. 5 shown the nose 2 in position to move forward. However, it may take repeated attempts to reorient the nose 2 before the tubing is in position to advance. Once the tool is in the proper position, however, the locking mechanism prevents further rotation, which could cause the nose to be stopped by the obstacle again. As the tubing progresses down the hole, further obstructions are handled in the same way, by the slight retraction of the tool, which unlocks the mechanism 6, rotating the nose to a new position and testing the new position by resuming forward motion. This process is repeated as need.

Attachment of the guide shoe 1 to the tubing string (not shown) is provided by a threaded female connection 7 (with threads 7 a) mating to a matching male connection on the tubing string.

FIG. 6 is an enlarged side cut-away view of the invention showing the internal orienting mechanism 6 in the unlocked position. Here, the pawls 10 are shown in the retracted (unlocked) position. The body 3 and nose 2 are free to rotate. Note also the exit port 2 a and the outlet line 2 b that can deliver fluids to the well hole, as desired.

FIG. 7 is an enlarged side cut-away view of the invention showing the internal orienting mechanism 6 in the locked position. Here, the pawls 10 are shown in the deployed (locked) position. The body 3 and nose 2 are now locked in position.

FIG. 8 is a detail view of the internal orienting mechanism shown in the unlocked position. In this view, the mechanism 6 is shown in its full form. Here, the shaft 5 is shown in the retracted position. The pawl 10 is attached to the shaft and is free to rotate as discussed above. The cylinder 12 remains fixed within the body 3. As the shaft 5 turns, it also tries to force the body forward (because of the ridged blades 4). The body will move forward when the pawls 10 come to the next ratchet position (e.g., 14 or 14 a on cylinder 12. At that point, the body is pushed forward and the pawl 10 engages the ratchet tooth 14 or 14 a, for example, and the cylinders lock together as shown in FIG. 9. At that point, the guide shoe can be moved forward to determine if the nose is able to bypass the obstacle.

The present disclosure should not be construed in any limited sense other than that limited by the scope of the claims having regard to the teachings herein and the prior art being apparent with the preferred form of the invention disclosed herein and which reveals details of structure of a preferred form necessary for a better understanding of the invention and may be subject to change by skilled persons within the scope of the invention without departing from the concept thereof. 

1. A guide shoe for well boreholes comprising: a) a cylindrical body; b) an eccentric nose, rotatably attached to said cylindrical body; and c) an orientation mechanism, attached between said body and said eccentric nose, whereby said orientation mechanism is designed to allow free rotation of the body and nose during the insertion of said guide shoe when said orientation mechanism is in a first position, and to lock said nose in a fixed position when said orientation mechanism is in a second position.
 2. The guide shoe of claim 1 further comprising at least one spiraled, ridged blade extending outward from said cylindrical body.
 3. The guide shoe of claim 1 further comprising a plurality of spiraled, ridged blades extending outward from said cylindrical body.
 4. The guide shoe of claim 1 wherein the orientation mechanism includes a ratchet and pawl assembly.
 5. The guide shoe of claim 1 wherein the orientation mechanism comprises: a) a) a first cylinder, said first cylinder having an open center and an outer circumference, said first cylinder being positioned in said cylindrical body b) at least one pawl, formed on the outer circumference of said first cylinder; c) a hollow shaft, fixedly attached to said first cylinder and passing through the open center of said first cylinder; d) a second cylinder, said second cylinder having an open center and an outer circumference, said second cylinder being oppositely disposed from said first cylinder on said hollow shaft, said second cylinder being rotatably positioned on said hollow shaft; and e) a ratchet mechanism having a receiver for said at least one pawl, formed on the outer circumference of said second cylinder, such that when said pawl and receiver are aligned and said hollow shaft moves in a lateral direction with respect to said first and second cylinders, said pawl locks into said receiver.
 6. The guide shoe of claim 1 wherein the cylindrical body is hollow.
 7. The guide shoe of claim 6 wherein the eccentric nose further comprises: a) an outlet nozzle formed in said eccentric nose; and b) a passageway formed in said eccentric nose and being in fluid communication with said outlet nozzle and said hollow cylindrical body.
 8. A guide shoe for well boreholes comprising: a) a cylindrical body; b) an eccentric nose, rotatably attached to said cylindrical body; and c) a means for orientating said eccentric nose, attached between said body and said eccentric nose, whereby said means for orientating said eccentric nose is designed to allow free rotation of the body and nose during the insertion of said guide shoe when said orientation mechanism is in a first position, and to lock said nose in a fixed position when said orientation mechanism is in a second position; and d) a means for attaching said guide shoe to a well tubing string.
 9. The guide shoe of claim 8 further comprising at least one spiraled, ridged blade extending outward from said cylindrical body.
 10. The guide shoe of claim 8 further comprising a plurality of spiraled, ridged blades extending outward from said cylindrical body.
 11. The guide shoe of claim 8 wherein the means for orientating said eccentric nose includes a ratchet and pawl assembly.
 12. The guide shoe of claim 8 wherein the means for orientating said eccentric nose comprises: a) a first cylinder, said first cylinder having an open center and an outer circumference, said first cylinder being positioned in said cylindrical body; b) at least one pawl, formed on the outer circumference of said first cylinder; c) a hollow shaft, fixedly attached to said first cylinder and passing through the open center of said first cylinder, said hollow shaft also being positioned within said cylindrical body; d) a second cylinder, also being positioned within said cylindrical body, said second cylinder having an open center and an outer circumference, said second cylinder being oppositely disposed from said first cylinder on said hollow shaft, said second cylinder being rotatably positioned on said hollow shaft; and e) a ratchet mechanism having a receiver for said at least one pawl, formed on the outer circumference of said second cylinder, such that when said pawl and receiver are aligned and said hollow shaft moves in a lateral direction with respect to said first and second cylinders, said pawl locks into said receiver.
 13. The guide shoe of claim 8 wherein the cylindrical body is hollow.
 14. The guide shoe of claim 13 wherein the eccentric nose further comprises: a) an outlet nozzle formed in said eccentric nose; and b) a passageway formed in said eccentric nose and being in fluid communication with said outlet nozzle and said hollow cylindrical body. 